what is aluminum profile bending?
Aluminum profile can be extruded and bent to specified tolerances or to standard dimensional tolerances. While a product’s dimensions and bend angles can be methodically measured and re-measured, the end product will only be as precise as the aluminum profile bending machine or method used.
What are the 3 important parameters of aluminum profile bending?
Several factors should be considered when choosing which bending process is appropriate for a certain product. Aluminum profile bending engineers can provide crucial input on the bending, shaping, and forming of aluminum during the design phase of a project. Deformation of the inside or outside radii can be a design issue and can also determine which forming process to use.
- What tolerances, or deviations, are expected on the inside radius, the outside dimension radius, and the overall length of the part?
- What surface areas are critical for appearance?
- What mechanical strength is required?
The product’s alloy, temper and cross-section also are important considerations.
Once these factors are determined, aluminum profile bending manufacturers can begin the bending process using one of the following five common bending and forming methods.
What are the 5 methods for bending aluminum profiles?
Roller and roll bending
Aluminium profile bending are used to form aluminium profiles.
What is the working principle of aluminum profile bending machine?
3-roll bending pushes an extrusion around three different rolls placed in a triangular shape. The rolls are adjusted to form a precise angle, up to a 360-degree rotation, that can roll horizontally or vertically. As the extrusion is slowly moved across the power-driven rollers, it begins to curve and bend.
Extrusions are limited to a single bend per cycle, meaning a higher angle of bend would take longer to reach the desired angle. Though it may take longer, the maximum bend radius is unlimited. Symmetrical profiles are preferable for roll bending.
It is the forming of aluminum profiles in one axis by a multi-roll bending machine. If the semi-finished product is not moved during the bending process, the distance between the rollers, their diameter and the depth of immersion determine the bending radius. To produce particularly large bends, the material is pulled through the roller bending machine and moved alternately. The distance between the rollers is gradually adjusted.
Why use a aluminum profile bender to bend aluminum?
Aluminium is a light metal with good-natured bending behaviour. To permanently bend it into a new shape, only lower forces are required than for other metals with the same cross-section. This makes its processing so simple that many adjustments can be made by hand at the installation site. However, professional processing machines promise the best results in consistent quality when bending aluminium.
In most cases, roll bending is the most flexible and cost-efficient bending method. A profile is guided between three adjustable bending rolls and gradually bent in the desired radius.
What are the models of aluminum profile bending machines?
Roll bending is the forming of profiles or sheets in one axis by a multi-roll bending machine. If the semi-finished product is not moved during the bending process, the distance between the rollers, their diameter and the depth of immersion determine the bending radius.
To produce particularly large bends, the material is pulled through the roller bending machine and moved alternately. The distance between the rollers is gradually adjusted. Roller bending machines with narrow rollers are used to form aluminium profiles. Roller bending machines work according to the same principle. They are used for gentle, one-dimensional forming of aluminium sheets.
Ram or Push Bending
Ram or Push Bending is ideal for components such as boat gunnels, portable structure supports, wheelchair frames and medical beds.
Ram or push bending, as the name implies, uses a ram to force the extruded metal piece on a bending die. A die pushes the extrusion onto the pressure dies, forcing the extrusion into your desired bent form. With programmable bend angles, this form of bending allows close proximity to multiple plane bends, though only one radius can be bent at a time. Ram bending offers inexpensive tooling and good bend precision with low per-bend cost.
In tension bending, an aluminium profile is clamped on both sides and stretched during the bending process. It is a gentle process that reduces the formation of cracks or pressure points at the bending point.
During stretch forming, an extrusion is placed along a rounded, fixed bending die and clamped in place on each end. The machine begins to swing the clamped ends downward to angles up to 180 degrees, and the extrusion is bent around the die to reach the desired form.
The bend radius is unlimited with this method. A stretch forming machine can bend, twist and lift an extrusion simultaneously to create unique, specified shapes and angles for parts up to 25 feet long. This method also offers the most accurate and consistent bending through elongation control. Because of the way the rounded, fixed bending die pushes on the extrusion, stretch forming has the least amount of surface distortion and traffic marking on the extruded piece.
Stretch forming is commonly used for parts with a larger bend radius, as the minimum bend radius is generally two to three times greater than other forming/bending methods.
Hydraulic Rotary Draw Bending
In the hydraulic rotary draw bending process, manufacturers place extruded aluminum onto a bender and hold it in place with a stationary or sliding pressure die and clamping block. The round bending die, powered by hydraulics, is rotated up to 90 degrees, bending the extrusion as it rotates. With this method, an extrusion can only be bent one radius at a time.
Incorporating a mandrel or other tool component to grip the rotary die can prevent creasing or misshaping of the product, though its use isn’t required. The single axis-controlled revolution can bend within one-tenth of a degree for extremely precise bend angles.
Hydraulic bending is often used when forming round tubes or pipes for applications such as handrails, and is ideal for extrusions with a large diameter, such as building signage.
ElectricRotary Draw Bending
The electric rotary draw method is best for applications that require multiple bends per part in close proximity to each other, or different radii bends for each part.
Electric rotary draw bending uses the same process as the hydraulic method, but allows faster setup. The bends also are more accurate and easily repeated because angles and rotations can be automated in a machine’s programmable logic controller. Rotations of the extruded aluminum also can be mechanized for variable plane bends.
Each of these bending methods has various benefits. Designing for success and determining the best method ultimately comes down to an end product’s desired tolerance, appearance and strength.
Which aluminum alloy profile bends best?
Aluminium is a good-natured material that is easy to bend. Once bent into shape, the sheet or profile retains its bending condition permanently. Provided no mistakes were made during bending, the formed semi-finished product remains in the desired position.
Formability of aluminum profile
- Series 1xxx are the Aluminum alloys with 99.00% pure aluminum. They have little structural value. They are very ductile in the annealed condition and have excellent corrosion resistance.
- Series 2xxx are the Aluminum – Copper alloys. These alloys have excellent machinability, limited cold formability (except in the annealed condition) and less corrosion resistance than other alloys, which is why they are anodized prior to usage.
- Series 3xxx are the Aluminum – Manganese alloys. With an addition of 1% Manganese, these alloys have no significant loss in ductility, good corrosion resistance, and very good formability. This series is one of the most preferable for forming applications.
- Series 4xxx are the Aluminum – Silicon alloys. This series has the addition of silicon, thus lowering the melting point and for this reason, it is used entirely for manufacturing welding wire.
- Series 5xxx are the Aluminum – Magnesium alloys. They exhibit a very good combination of high strength, resistance to corrosion, formability, and good weldability.
- Series 6xxx are the Aluminum – Magnesium – Silicon alloys. These heat treatable alloys exhibit great strength, good corrosion resistance, and ease of formability. The are mainly used in architectural applications.
- Series 7xxx are the Aluminum – Zinc – Magnesium and Aluminum – Zinc – Copper alloys. They exhibit very high strength, making them very difficult to form.
Thickness and bending radius of aluminum profile bending
Another factor to consider is that during the process of bending, the metal hardens and strengthens by reason of the working effect. Apart from alloy selection, thickness and bend radius are also critical factors that must be considered. The table below shows the permitted bend radii for 90o bending.
Percentage of aluminum profile bending elongation
A third factor to be considered is that formability of a specific alloy can be found in the percentage of elongation and the difference between yield strength and ultimate tensile strength.
This rule states that the higher the elongation value (the wider the range between yield and tensile strength), the better the forming ability of the alloy.
From the aforementioned descriptions of alloys and the data shown in table 3 (below), it is quite obvious that the best series for forming, and thus for bending, are series 3xxx, 5xxx, and in some cases 6xxx. Series 2xxx and 7xxx are not to be considered and thus should be avoided due to being extremely strong. They are difficult to form in any way.
Top 3 Aluminum Alloys For Bending
- 3003：This would be the best solution for most application. This alloy exhibits medium strength, the best cold workability together with high elongation such as 25% and one of the biggest differences between yield and tensile strength of 14 Ksi (Kilo-pound of force per square inch) at 0 temper – annealed, followed by the H14 temper which is partially annealed and strain hardened.
- 5052：5052 is a close second. At the annealed temper, it has an elongation of 20% and the difference between yield and tensile strength of 21.5 Ksi. It is the highest strength alloy of the more common non-heat treatable grades. It has excellent corrosion behavior and in the annealed condition has better formability than 3003 or even 1100 alloys, with 21.5 Ksi of difference between yield and tensile strength and up to 20% of elongation.
- 6061： This is one of the most versatile of the heat treatable family of alloys. In the annealed condition, it can be used for bending since the difference between yield and tensile strength is 10 Ksi and elongation is up to 18%. When moving up to T4 and T6 tempers, however, bending ability tends to decrease. Bending these temered alloys is not impossible, but requires great caution and probably larger bending radii to avoid cracking.
7005 and 2024 alloys are not recommended for bending, since they are both alloys with great strength and forming capabilities which are very limited even in annealed condition.